Machine tool



April 9, 1946. J. 0. WILSON MACHINE TOOL Filed May 20, 1942 11 Sheets-Sheet l mvemon JOl/V C MUM ATTORNEVS April 9, 1946. J J. c. WILSON MACHINE TOOL Filed May 20, 1942 ll Sheets-Sheet 2 M -MW April 9, 1946. J. c. WILSON 2,398,268

MACHINE TOOL Fild May 20, 1942 11 Sheets-Sheet 4 INVENTOR JOH/VCMZSOV ATTOQAEYS April 9, 1946. J. 0. WILSON 2,398,258

\ I MACHINE TOOL Filed May 20, 1942 11 Sheets-Sheet 7 April 9, 1946. J. 0. WILSON MACHINE TOOL Filed May 20. 1942 11 Sheets-Sheet 8 April 1946. J. c. WlLS ON 2,398,268

MACHINE TOOL Filed May 20, 1942 ll Sheets-Sheet 9 INVENTOR W4 Jam ATTORN EYS J. C. WILSON MACHINE TOOL April 9, 1946.

Filed May 20, 1942 ll Sheets-Sheet 10 Jmmacfw ATTORN EYS Apiril 9, 9 6. J. c. WILSON 2,398,268

MACHINE TOOL Filed May 20, 1942 11 Sheets-Sheet 11 LEE-E1 INVENTOR JOIN 'C WLS'OV ATl'ORN EYS Patented Apr. 9, 1946 UNITED STATES PATENT OFFICE MACHINE TOOL John 0. Wilson, Springfield, Ohio, assignor to The Thompson Grinder Company, Springfield, Ohio, a corporation of Ohio Application May 20, 1942, Serial No. 443,829

14 Claims.

It is another object to provide a control mechanism of the type set forth in the preceding paragraph, which is provided with means for varying the relative travel between the work piece to be machined and the machining tool.

It is a further object to provide a control mechanism for automatically controlling the tool holder of a machine tool so that thetool" holder remains stationary during one portion of the working cycle while the work piece is being moved, and moves during another portion of the working cycle along a curved line, while the work piece is held stationary.

Another object of the invention consists in the provision of a machine tool for machining surfaces of closed contour with straight and curved surface portions merging with each other, in which the machining tool is eccentrically journalled with regard to a rotary member and moved u the machining tool.

a machine tool as set forth in the preceding paragraph, in which the control mechanism for moving the machining tool along a curved line is operated selectively either manually or automati-' cally by hydromechanical means and controlled by electric means.

It is another object of the invention to provide a machine tool in which the tool holder holding the machining tool is provided with means for practically eliminating any swinging movement of These and other objects and advantages of the invention will appear more clearly from the following specification in connection with the accompanying drawings, in which:

Figure 1 shows the grinding machine in opera position for being machined according to the inalong a curved portion in response to a rotation of said rotary member by a predetermined angle.

t is a still further object to provide a machine tool, in which the work piece is supported by a reciprocable table, the operation of which is automatically controlled during a complete cycle, while the machining tool for machining the work piece is likewise automatically controlled so as to be held stationary during the movement of said table, and to be moved along a predetermined I curved line during a period between the end of vention.

Figures 5', 6 and 7 diagrammatically illustrate the relative movement of the work piece and a grinding wheel controlled according to the invention.

Figure 8 is a partial section along the line 8--8 of Figure 4, showingthe simultaneous machining of two opposite sides of the work piece.

Figure 9 is a transverse section through the support for the machine tool.

Figure 10 shows, partially in view and partially in section, a detail of Figure 9.

Figure 11 is a longitudinal section through the support for the machining tool.

Figure 12 is a section along the line l2l2 of Figure 11.

Figures 13, '14, 15, and 16 diagrammatically illustrate the operation of the device shown in Figure 12.

Figure 1'7 is a section along the line 11-11 of Figure 18.

Figure 18 is. a section along the line l8l8 of Figure 17. 1

Figure 19 illustrates the hydraulic control systern for the device according to the invention.

Figure 20 illustrates the electric control circuit for the device according to the invention.

Figure 21 shows the circuit of Figure 20 in simplified form.

Figure 22 is an energizing chart, indicating th period during which the various solenoids are energized when the machine performs a working cycle.

Figure 23 shows a manually operable switch in open position, and

Figure 24 shows the switch of Figure 23 in closed position.

General arrangement Referring now to the drawings in detail and to Figures 1 to 3 thereof in particular, the structure shown therein constitutes a grinding machine with a reciprocable table III for supporting a work piece, generally designated II, and indicated in dot-dash lines in Figure 1. The work piece, which may have the shape of the work piece shown in Figure 4, is mounted in a fixture, generally designated l2. The fixture l2 comprises a jaw l3 with a V-shaped recess M for engaging one end of the work piece ll, while the other end is engaged by a, clamping member l5 which is supported by a bolt I6, partially surrounded by a spring I! and threaded into a supporting member l8. A nut l8 clamps the member i5 against the right hand end of the work piece, and presses the latter against the supporting member l8.

The work piece shown in the drawings is I- beam shaped in section, as will appear from Figure 8, and constitutes a connecting member, which may, for instance, be used for internal combustion engines. Both sides of the work piece are of the same shape and are to be ground by two identical grinding units on each side of thetable i8. Only one of the grinding units will be explained in detail, while corresponding parts of the other grinding unit will carry the same reference numerals, however, with the additional letter a.

The grinding unit substantially comprises a grinding wheel 28 mounted on a shaft 2| and driven by an electric motor 22 ,by means of pulleys 23 and 24 operatively interconnected by a belt 25. The shaft 2|, together with the driving mechanism therefor, is supported by a supporting slide 26, which is movable toward and away from the work piece so as to allow spacing of the grinding wheels 28, 280, from each other for inserting or removing a work piece therebetween.

Duringthe working operation, the work piece H is reciprocated in longitudinal direction thereof, while the grinding wheels 28, 28a rotate without moving longitudinally with regard to the work piece.

The grinding wheels 28, a are adapted to move transversely with regard to the adjacent lateral surface of the work piece, but are prevented from doing so during the greater part of the machining operation. However, when the work piece i I has moved to such an extent that the grinding wheels 28, 20a are about to machine the curved end surfaces 21 and 28 of the work venient manner for instance by screws 33, a dishshaped member 34 which, in its turn, has connected thereto, in any convenient manner for instance by screws 35, a segmental gear 36. The member 34 and gear 36 are provided with oval bores 31 and 38 respectively.

The gear 36 is adapted to mesh with racks 38 and 48, forming part of two piston rods 4| and 42 respectively. The piston rod 4| interconnects two spaced pistons 43 and 44 respectively mounted in a cylinder 45. The cylinder 45 is closed at its ends by closure members 46 and 47 which have bores therethrough, connected with conduits 48 and 48 respectively.

To prevent rotation of the pistons 43 and 44, the piston rod 4| is provided with a longitudinal ridge 58, engaged by a guiding member 5|. The cylinder 45 has furthermore connected thereto a conduit 52. Similarly, the piston rod 42 interconnects two pistons 53 and 54 reciprocable in a cylinder 55, the ends of which communicate with conduits 56 and 51 respectively, while a conduit 58 is connected with the cylinder 55 at a point between-the ends of the cylinder.

The piston rod 42 also comprises a ridge 58 engaged by a guiding member 68 for preventing rotation of the pistons 53 and 54 in the cylinder 55. The cylinders 45 and 55 are connected in any convenient manner, for instance, by screws 6|, to the casing 28.

As will be seen from Figure 11, the drum 32 is prevented from moving longitudinally in the casing 28 by means of the flange 62 connected to the drum 32 and the flange 63, forming a part of the member 34. To provide for proper lubrication between the drum 32 and the casing 28, an oil receiving annular recess 84 is provided.

The drum 32 has inserted therein and in any desired manner connected thereto, a supporting member 65, carrying the shafts 66, 61, 68 and 68 of a gear train respectivel comprising the pinions 18, II, 12 and 13. The shafts 66 and 68 are journalled in anti-friction bearings 14 and 15 respectively. The pinion 13 is also connected with a threaded extension 16 threadedly engaging a nut, 11 which is rigidly connected, by means of screws 18, to a slidable block 18.

The block I8 has a slot 86 passing from one side of the block 18 to the bore 8| in the block 18, and is provided with one or more clamping screws 82 transversing the slot 88. The block 18 is slidable between a guiding member 83 and the surface 84 0f the drum 32. A key 85, connected to the drum 32 by means of screws, engages a groove 86 in the block 18. The guiding member 83 may be adjusted by a screw 81 supported by the drum 32.

The drum 32 is composed of two parts 88 and 88, which are properly located with regard to each other by means of a key 88, and are connected with each other by screws 8|. To properly lubricate the guiding surfaces for the block 18, an oil groove system, generally designated 82 is provided, which communicates with the annular recess 64, and also communicates with oil channels 83 for lubricating the shafts 61 and 68 pertaining to the pinions H and 12.

Mounted in the bore 8| of the slidable block 18 is the shaft 2|. The shaft 2| carries, at one end thereof, the grinding wheel 28 and, on the other end, the ulley 24. The end adjacent the pulley 24 extends through a closure connected to the cylinder assembly, generally designated 86, and carrying the cylinders 45 and 56. A bearing member 84 is clamped in the bore 8! of to and engaging the nut 11. Inasmuch as the latter is stationary in the slidable block 19,,it

will be obvious that rotation of the threaded extension I6 causes longitudinal movement of the slidable block I9, thereby moving the bearing member 94 relative to the center of the drum 32. This movement will cause a corresponding movementof the grinding wheel 20 so that the grinding wheel 20 will be fed toward the work piece surface to be machined.

The rotation of the pinions I0, II, I2 and I3, which mesh with each other, is eifected by a shaft 98, which is drivingly connected with the shaft 56 pertaining to the pinion 10. The shaft 90 is supported by a sleeve 99 which, in its turn,

is carried by a casing I00, supported by and rotatable with the drum 32.

Connected to the shaft 98 is a worm wheel IOI meshing with a worm I02 keyed to a shaft I03. Also rotatably connected to the shaft I03 is a hand wheel I04 and. a star wheel I05. The star wheel I05 is adapted to cooperate with an indexing member I06 supported by the housing 29. When the star wheel I05 engages the indexing member I06, while the drum 32 continues its rotation, the star wheel I05 will be rotated by a predetermined angle, in this instance, 60

9 andll, rotadegrees, as indicated in dot-dash lines in Figure 9, showing the star wheel at the time when it engages the indexing member I06, and at the time when it has moved or rolled over the indexing member I06. Due to this rotation of the star wheel I05, also the shaft I03 rotates by 60 degrees, so that the worm I02 imparts a corresponding rotation on the shaft 98 which, in its turn, rotates the pinions 10, II, 12 and I3. As previously mentioned, rotation of the pinion 13 causes movement of the slidable block I9.

When the star wheel I05 has moved beyond the indexing member I06, it stays in its respective angular position relative to the shaft I03 'until the star wheel, during the rotation of the drum 32 in the same direction, again engages the indexing member I00.

If it is desired for the purpose of setting the machine to manually effect a sliding movement while the work the drum 32. It is furthermore assumed that when, at the end of each cycle, the grinding wheel 20 is substantially in the position indicated in dot-dash lines in Figure 4. the eccentricity between the center of the grinding wheel 20 and the center-of the drum 32 is to be increased so that the grinding wheel is fed further toward the surface I08, so as to take off more material there from. It is also assumed that the grinding wheel.

20 has just been fed toward the surface I03 so as to occupy the position indicated in dot-dash lines in Figure 4, while the star wheel I05 has, just moved over the indexing member I06 in anticlockwise direction with regard to Figure 9, or in clockwise direction with regard to Figure 13. The star wheel I05 now occupies the position P indicated in dot-dash lines in Figure 9. In this position, the star wheel I05 has completed its angular movement and will not be actuated again until the drum 32 has performed a complete rotation.

When the star wheel I05 occupies the position I of Figure 9, the cylinder assembly 06 is assumed to occupy the position shown in Figure 13. In

this position, the segmental gear 38 and the racks 39 and 40 are hydraulically locked by fluid admitted through conduits 49 and 55 into the lefthand portion of the cylinders 05 and 55 respectively.

As will be clear from Figure 13, the fluid in cylinder tends to move the rack 39 toward the right to impart a clockwise movement on the se mental gear 36, while the fluid in cylinder 55 tends to move the rack 40 toward the right, endeavoring to impart an anti-clockwise movement on the gear 35. Since the forces acting on the piston 53 equal the forces acting on the piston 53, the segmental gear 30, is held stationary. Consequently, the grinding wheel 20 is now held in the position indicated in dot-dash lines in Figure 4, piece II, together with the fixture I2 and table I0, moves toward the left with regard to Figure 4. Since the grinding wheel 20 is rotating about its axis, it will be clear that the grinding wheel will grind the surface I08.

When the grinding wheel 20 has reached the position indicated in dot-dash lines in Figure 5 of the slidable block 19, the operator rotates the hand wheel I04, which will result in a rotative movement of the shaft 98, and in a rotation of the pinion I 3, in the manner previously described. To facilitate the control of the rotation of the shaft 98, a dial I0! is connected to the shaft 90. The rotation of the drum 32 is efiected by the cylinder assembly 90, as will presently appear.

Rotative movement of the drum Referring to Figures 13, 14, 15 and 16, dia

grammatically illustrating various positions of and is just about to machine the surface 28, a control mechanism, which will be described later, causes the fluid in the left-hand end of the cylinder 55 to exhaust through conduit 56, while fluid pressure is admitted through conduit 51 into the right-hand end of the cylinder 55. The forces now acting on the pistons 03 and 50 do not oppose each other, but act through the racks 39 and 40 on the gear 35 in such a manner that the gear 36 rotates in clockwise direction with regard to Figure 14, or in anti-clockwise direction with regard to Figure 9. This, in turn, brings about a correspondingdegree rotation of th drum 32 to which the gear 36 is connected.

As a result thereof, the grinding wheel 20 performs such a movement, in addition to its rotation about its axis, that its periphery will move along a line conforming to the contour of the surface 28, thereby machining the latter. In other words, the grinding wheel 20 moves from the position indicated in dot-dash lines in Figure 5 through the position indicated in Figure 6 into the position indicated in dot-dash lines in Figure 'I. When the grinding wheel 20 substantially occupies the position indicated in dot-dash lines in Figure '7 so that the grinding wheel 20 is about to machine the surface 91, the segmental gear 35 and the racks 39 and 60 substantially occupy the position shown in Figure 16, in which they are hydraulically locked by pressure fluid admitted through conduits 51 and 48 into the respective right-hand ends of the cylinders 45 and 55.

It is to be noted that when the rack 40 has moved from Figure 14 position toward the left to such an extent that, as indicated in Figure 15, the rack 39 does not mesh with the teeth on the gear 36, the fluid in the left-hand end of the cylinder 45 is exhausted through the conduit 49, and fluid pressure is introduced through the conduit 48 into the right-hand end of the cylinder 45, so that the rack 39 moves toward the left without meshing with the teeth of the gear 36.

Since, as mentioned above, the gear 36 in Figure 16 is again hydraulically locked, no further movement of the grinding wheel 20 takes place, with the exception of its rotation about its axis. Inasmuch as the work piece II is now moving toward the right. as indicated by the arrow R in Figure 7, the grinding wheel 20 now machines the surface 91.

When the grinding wheel 20 has reached the left end of the straight surface 91 and is about to machine the curved surface 21, a control mechanism, which will be described later, causes exhaust of the fluid in the right-hand end of the cylinder 45, while fluid pressure is admitted to the left-hand end of the cylinder 45 through the conduit 49.

The forces acting on the pistons 43 and 53 now do not oppose each other, but cooperate with each other in bringing about a rotation of the earv 36 in clockwise direction with regard to Figure 16, or in anti-clockwise direction with regard to Figure 9. The gear 36 then rotates by 180 degrees so that, at the end of this rotation, the gear 36 again occupies the position shown in Figure 13, while the drum 32 occupies the .position shown in Figure 9. During this rotation, the grinding wheel 20, due to its eccentricity with regard to the center of the drum, performs such a movement that the periphery of the grinding wheel moves along the surface 21. thereby machining the same.

Just before the grinding wheel 20 again engages the straight surface I08, i. e., just before the gear 36 completes its 180 degree rotation, the star wheel I rolls over the indexing member I06, thereby imparting a rotation on the shaft I03, which latter, by means of the worm I02 connected, thereto, and meshing with the worm wheel IN on the shaft 98, effects 8. corresponding movement of the pinions 10, 1|, I2 and I3. Rotation of the pinion 13 results in a longitudinal.movement of the slidable block 19,-as mentioned under General arrangement, thereby increasing the eccentricity of the grinding wheel 20 with regard to the drum 32. In other words, the grinding wheel is fed further into the material of the work piece to be machined.

When the star wheel I05 has rolled over the indexing member I06, no further longitudinal movement of the slidable block 19 is eifected, while substantially simultaneously "the rotation of the drum 32 is stopped. The segmental gear 36 then again occupies the position shown in Figure 13. In the meantime, i. e., when during the last mentioned rotation of the gear 36, the rack 40 has disengaged the teeth of the gear 36, fluid is exhausted from the right-hand end of the cylinder 55, while fluid pressure is admitted to the left-hand end of the cylinder 55 so as to bring the rack 40 from Figure 16 into Figure 13 position. When the gear 36 occupies the posicylinder I 28.

'tion shown in Fi8ure13, it is again locked, as previously explained. Inasmuch as the work piece II now moves toward the left, as indicated in Figure 5, the grinding wheel 20 will further machine the surface I08 and a new machining cycle is then started.

' It will be appreciated that, at the point where the feeding takes place, a very slight step may occur. To eliminate this step, the operator, following the last mentioned cycle, moves the indexing member I06 in longitudinal direction in the bore I I9 so that the indexing member I06 will not be engaged by the star wheel I05 when the drum 32 performs a complete rotation. In this way, there will be no further feeding of the grinding wheel, so that the machined surface will be completely smooth (sparked out) after a further complete rotation of the drum, following the last mentioned cycle.

The indexing member I06 has two spaced recesses corresponding to its operative and inoperative position, which recesses are engaged by a detent member I20.

When the machining operation of the work piece II has been completed, the slides 26 and 26a and, therefore, also the grinding wheels 20 and 20a are retracted from th work piece, as indicated in Figure 1, so that the work piece may be removed and replaced by an unmachined work piece. moved so as to bring the grinding wheels 20 and 20a into their operative positions. The grinding wheels are brought into their final work piece engaging position by a corresponding movement of the hand wheels I04 and I04 a. This movement has been explained under General arrangement and brings about a movement of the slidable block I9, thereby bringing the grinding wheels 20 and 2011 into the desired eccentricity with regard to the drums 32 and 32a pertaining thereto.

Operation of the cross slides Referring to Figures 17 and 18 showing the supporting or cross slide 26, it will be seen that the latter has a slant guiding surface I09 engaging a correspondingly shaped guiding surface on the support or foot IIO of the machine. The slide 26' has furthermore a traight guiding urface III engaging a corresponding guiding surface on the support I I0.

Connected to the slide 26 is an extension II2, the lower end of which is provided with a bore II3, through which passes a reduced end II4 of a screw I I5. Connected to the reduced end 'I I4, for instance by means of a nut H6, is a hand wheel 1, which is also keyed to the reduced portion IN. The screw II5 threadedly engages two nuts H8 and I2I which are rigidly connected to an auxiliary slide I22 so that rotation of the screw II5 will move the slide I22 in one or the other direction depending on the direction of rotation of the screw I I5.

The auxiliary slide I 22 is slidable in a dovetailed portion I23 of the supporting or cross-slide 26. Connected to the auxiliary slide I22 i an extension I24, engaging a reduced portion I25 of a piston rod I26, which is connected to a fluid operable piston I21 reclprocably mounted in a The cylinder I28 i connected to the support I I0. The extension I24 is clamped, by means of a nut I29, against the shoulder I30 of the piston rod I 26.

Fluid pressure may be admitted selectively to one or the other side of the piston I21 50 as to move the piston rod I26, and thereby the exten- The slides 26 and 26a are then again asoaaes sion I24 connected to the auxiliary slide I22. in one or the other direction.

Inasmuch as the auxiliary slide I22 is looked through the screw IIIS and the extension "2, clamped between the threaded part of the screw H8 and the hand wheel II1, to the supporting or cross slide 28, a reciprocatory movement of the piston I21 and the extension I24 will not only result in a reciprocatory movement of the auxil= iai'y slide I22, but also of the cross slide 28.

To vary the minimum distance of the grinding wheel from the work piece without changing the total stroke of the piston I21, the operator rotates the hand wheel H1 in one or the other direction, thereby rotating the screw H8. Inasmuch as, at this time. the fluid in the cylinder I28 holds the piston I21, and, thereby, the piston rod I28 and extension I24 connected to the auxiliary slide I22, stationary, rotation of the screw II8 causes the latter to move out of or into the nuts I I8 and HI depending on the direction of rotation of the hand wheel II1, so that the screw H8 performs a longitudinal movement. This longitudinal movement causes the cross slide 26, connected to the screw II8 by the extension II2. likewise to perform a longitudinal movement so as'to move the grinding wheel 28 toward or away from the work piece.

Hydraulic circuit Referring now to Figure 19 illustrating the hydraulic control circuit for the device according to the invention, this hydraulic circuit comprises amain pump I29 connected by a conduit I38 with a fluid reservoir or tank I3I. communicates through conduit I32 with a conduit I33. The conduit I33 has one end connected to a solenoid controlled four-way valve I34 which, in its turn, communicates through the conduit 48a with one end of the cylinder 85a, and through the conduit 4801, containing a check valve I35, with the other end of the cylinder 45a.

A further conduit I38 leads from the solenoid controlled valve I38 to a conduit I31. The conduit I31 has one end connected to a solenoid controlled four-way valve I38, which communicates through conduit I89 with the conduit I38, and through conduit 58a, comprising a check valve I88, with one end of the cylinder 55a, while the other end of the cylinder 55a communicates through conduit 5111 with the valve I38. The check valves I38 and I 48 are adapted to be bypassed by conduits MI and I82, respectively comprising a choke I43 and I48.

The valves I35 and M3 and the conduit I4I constitute a choke-check arrangement, which allows unrestricted flow from the cylinder 45a and the conduit 89a to the valve I35, while permitting only a restricted flow of, fluid from the valve I38 through the choke valve I83 and the conduit 49a into the left hand end of the cylinder 45a.

Also communicating with the tank I3I is a conduit I45 leading to a manually operable, four-way valve I 88 which controls the flow of fluid to and from the cylinder I280: which, in its turn, controls the movement of the cross slide 28a.

The conduit I48 comprises a spring loaded check valve I88, which is adapted to choke the fluid expelled from the cylinder I28a to the tank I3I so that the cross slide cannotbe retracted with a sudden push, which would damage the machine.

The cylinder I28a is connected with the fourway valve I48 through the conduits I41 and I88. The four-way valve I48 furthermore communi- The tank I3I cates through a conduit m with a conduit I58 comprising a throttle I 8|, and having one end connected through conduit I82 with the pressure side of the pump I29.

Branching of! from the conduit I58 is a conduit I53 leading to the conduit I31. The conduit I53 furthermore leads to a manually operable the cylinder :28 by conduits I55 and I58. Furthermore, a conduit I51 connects the four-way valve I54 with the tank I3I. The conduit I51 comprises a spring loaded check valve I8 I, similar to and for the same purpose as the spring loaded check valve I88.

The pressure line I52 leads to a solenoid controlled master valve I58 which is connected, by means of a conduit I59, with a retarding valve I88, which latter communicates through a conduit I8I with another retarding valve I82. The retarding valves I88 and I82 are choke valves which are normally open, but are adapted to be moved into choking position by means of the lever arms I88 and I82, which are respectively actuated by the ends of the table I8. In this way, the exhaust from the table operating cylinder I88 is throttled whenever the plunger I69, reciprocable in the cylinder I88, reaches one or the other end of its stroke.

The retarding valve I82 is connected through the conduit I83 with a solenoid operated valve I84, which is normally held closed, but is adapted to be opened electrically for connecting the conduit I53 with the conduit I85 leading to the tank I3I.

The master valve I58 is furthermore connected through conduits I88 and I81 respectively with the ends of a cylinder I 88, having reciprocably mounted therein a. plunger I89 for reciprocating the table I8 supporting the work piece II.

Similar to the cylinder 45a, the cylinder 45 is connected through conduits 48 and 49 with a solenoid operated valve I18. The conduit 49 comprises a check valve I1I adapted to be by-passed by a conduit I12 with a choke I13. The fourway valve I18 also communicates through a conduit I14 with the conduit I31.

The supply of fluid to and from the cylinder 55 is controlled by -a solenoid operated four-way valve I15, which communicates through the conduit I18 with the conduit I33. Th'e conduit 51 comprises a check valve I11 adapted to be bypassed by a conduit I18 with a. choke I19.

The operation of the hydraulic system shown in Figure 19 is as follows:

It may he assumed that the plunger I89, connected to the table I II and reciprocable in the table control cylinder I88, is in its right hand position, and that the table is loaded with a work piece. It may further be assumed that the piston rods I28 and I26ci, pertaining to the cylinders I28 and I28a for controlling the movement of the supporting or cross slides 28 and 28a, are in their retracted position which, considering Figure 19, is the right hand position with regard to the piston rod I28, and the left hand position with regard to the piston rod I28a.

To bring the grinding wheels into work piece engaging position, the operator shifts the valves I48 and I54 so that fluid pressure from the pump I29 passes through the conduit I58 and the valves result thereof, the piston rods I26 and I26a move toward each other and, thereby, toward the work piece, while fluid is expelled from the cylinder I28 through valve I54 and conduit I51 into the tank I3I, and from cylinder I28a through valve I46 into the tank I3I.

The inward movement of the piston rods I26 and I26a is controlled by the setting of the spring loaded check valves I8I and I88. When the cross slides 26 and 26a have been moved inwardly by the piston rods I26 and I26a, the operator, by actuating the hand wheels I84 and I84a, brings the grinding wheels 28 and 28a into proper engagement with the workpiece II, as described under "General arrangement.

Now all parts are ready for beginning the actual machining operation. The operator, therefore, closes an electric circuit, which will be described later, so as to shift the master valve I58 into position for admitting pressure fluid from the pump I29 through conduit I52, master valve I56 and conduit I61 into the right hand end of the table controlling cylinder I68. Furthermore, the valve I66 is electrically opened, thereby establishing fluid connection between the left hand end of the table controlling cylinder I68 through conduit I66, master valve I58, conduit I52 with the pressure side of the pump I29. Furthermore, the valve I64 is electrically opened so as to establish fluid connection between the left hand end of the cylinder I68 and the tank I3I through the conduit I66, master valve I58, conduit I59, retarding valve I68, conduit I61, retarding valve I62, conduit I63, valve I64 and the conduit I65.

Therefore, the piston rod I26 and the table I8, connected thereto and supporting the work piece, move toward the left so that the grinding wheels occupy the position indicated in dot-dash lines in Figure 4, in which they begin to machine the surface I88 and I88a.

When the work piece on the table I 8 has moved toward the left to such an extent that the grinding wheels approach the position indicated in dot-dash lines in Figure 5, but have not yet reached the said position, the cam I82 (Figure 2) actuates the lever I62 so as to move the retarding valve I62 into choking or throttling position, thereby restricting the flow of fluid from the left hand portion of the cylinder I68 into the tank I3 I. This slows down the movement of the table I8. When the table I8 has moved toward the left to such an extent that the grinding wheels are in the position indicated in dot-dash lines in Figure 5, i. e., are at about the right hand end of the straight surfaces I88 and mm, the dog I83 (Figure 2) actuates a limit switch E, which controls the circuit of the solenoid pertaining to the valve I64, so as to deenergize the said solenoid. .As a result thereof, the valve I68 closes,

and no more fluid can be expelled from the left side of the table controlling cylinder I68. Consequently, the table In comes to a halt.

Now an electric control circuit, which will be described later, causes the solenoids pertaining to the valves I34, I38 and I18, I15 to respectively shift these valves so that fluid pressure is admitted to the cylinder assemblies 96 and 96a in a. manner previously described in connection with General arrangement so that the drum 32 causes the grinding wheel 28 to move alongthe curved surface 28, while simultaneously the drum 32a causes the grind ng wheel 28a to perform a corresponding movement.

When the grinding wheels have reached the position indicated in dot-dash lines in Figure 7, the master valve I 58 is electrically reversed so that pressure fluid from the pump I29 now flows through conduit I52, master valve I58 and conduit I66 into the left hand and of the table controlling cylinder I68, while 'the conduit I61 is connected with the conduit I59. Furthermore, the solenoid controlling the valve I64 is again energized so as to establish fluid connection between the conduits I63 and I65 leading to the tank I3I. Therefore, the pressure fluid acting at the left hand nd of the cylinder I68 causes the plunger I69 and the table I8, connected thereto, to move toward the right. The grinding wheels then machine the surfaces 91 and 91a (see Figures 7 and 8).

Shortly after the rightward movement of the table has begun, the cam I82 again releases the lever I62 so that the retarding valve I62 again opens. Both retarding valves I68 and I62 are now open so that the fluid expelled from the right hand end of the table cylinder I68 is not throttled. Therefore, the machining can take placeat a high advancing speed of the work piece.

When the work piece I I has moved toward the right to such an extent that the grinding wheel 28 approaches the position in which it will machine the surface 21, the cam I84 (see Figure 2) actuates the arm I68 so as to move the retarding valve I68 into throttling position. This throttles the exhaust from the right hand and of the cylinder I68, thereby slowing down the rightward movement of the table I8 and the work piece II, supported thereby.

When the grinding wheel 28 has reached the position at which it is about to machine the surface 21 (grinding wheel 28a has reached acorresponding position), the dog I85 engages the limit switch D, thereby causing deenergization of the solenoid controlling the valve I64. The valve I66 therefore closes, and prevents any further exhaust of fluid from the right hand end of the cylinder I68. As a result thereof, the table I8 comes to a halt.

The valves I36, I36, I18 and I15 are again electrically controlled so that the cylinder assemblies 96, 96a cause the grinding wheel 28 to move along the curved surface 21, while the grinding wheel 28a performs a corresponding movement. When the grinding wheels have reached a position corresponding to the position indicated in dot-dash lines in Figure 4, the master Valve I58 is again reversed and the valve I64 is again opened, so that another machining cycle may be performed, as previously described.

When the desired number of machining cycles has been performed so that the machining of the work piece is completed, the operator shifts the casing I81, which is shown in Figure 2 and will be described later, out of the path of the dogs I85 and I83. Furthermore, fluid pressure is admitted to the cylinders controlling the movement of the cross slides 26 and 26a so as to cause said slides and, thereby, the grinding wheels 28 and 28a to move away from each other and from the work piece. Fluid pressure is then admitted to one end of the table cylinder I68 so that the plunger I69 performs a complete stroke, thereby fully withdrawing the table and the work piece.

move the table and the new work piece again into initial position. The grinding wheels are then Electric circuit v Referring to Figure 20, the cam shows in die grammatic form the grinding wheels 20, 20a respectively supported by the supporting slides 26, 29a having cams I98 and 199. The cam I08 is adapted selectively to engage a pin or contact I99 or I95, thereby closing the normally open switch I92 or the normally open switch F.

One terminal of the switch E92 is connected, by means of a line i9t', with one terminal of the switch 202, while the other terminal of the switch I92 is connected, by means of the line I90, with the line I91 which, in its turn, is adapted, by

closure of the switch C to be electrically connected with the main supply line I95. The switch F, when closed, connects the line I99 with the line 290. One end of the line I99 is connected to one terminal of the normally open switch G, which is adapted to be closed by the cam we when the latter engages the pin or contact 202. The other terminal of the switch G is connected, by line 209, with theline 200. The normally open switch 204 is adapted to be closed by the cam I99 when the latter engages the con tact or pin 205. In closed condition, the switch 200 establishes connection between the line I92 and the line 209 leading to the terminal 201.

The terminal 201 is adapted selectively to be engaged by the switch blade A so as to connect the line 299 with the line 209, which latter comprises a solenoid DSl, pertaining to the master valve I99. The line 299 is connected with the main supply line 2W. Also connected with the main supply line 210 is a line 2, comprising a solenoid ESi, pertaining to the master valve I59.

The solenoid D81, when energized, shifts the master valve H in one direction, whereas the solenoid E81, when energized, shifts the master valve M9 in the opposite direction.

Furthermore connected with the main supply line 210 is a line 2! 2, comprising a solenoid ES4DS4, pertaining to the valve Hit. The line 2E2 is adapted to be connected by closure of the solenoid blade N with the line 2 l3. The blade N is controlled by a solenoid 213, which is located in the line I99. The line 213 is adapted to be connected by closure of the relay blade ER4 with the line 2B5, which latter is adapted to be connected with the line 216 by means of the relay blade DR4. The line 216 is connected to the line 211, which has one end connected to the main supply line I95 and is adapted to be connected with the line 213 by closure of the relay blade URL The line 2i8 is adapted to electrically communicate with the line 209 by means of the switch blade A.

A relay blade DRzDRs is adapted to establish electric connection between the line 219 and the line 220, which latter is connected to the main supply line i215, and is furthermore adapted to be connected with the line 22I by closure of the pressure switch K. The pressure switch K is hydraulically connected through a conduit 222 (Figure 13) with the cylinder 49, and is adapted to be closed in response to a predetermined pressure in the conduit 222. As will be clear from Figure 13, the pressure fluid acting on the left side of the piston 23 will be conveyed to the conduit 222 as soon as the piston 43, in its rightward movement, has moved beyond the port 223.

Theline 22! comprises a solenoid KS- andis 55. 1 ressure fluid acting on the right hand end of the piston 54 will be conveyed into the conduit 229 when the piston 94, in its leftward movement, moves beyond the port 221.

The line 22H also comprises a solenoid JS and is adapted to be connected with the line 228 by closure of the pressure switch J. The pressure switch J corresponds in its operation to that of the pressure switch K and pertains to the cylinder assembly 96a, whereas the switches K and M pertain to the cylinder assembly 96.

Connected with the line 228 is a line 220 adapted to be connected with the line 230 by closure of the pressure switch L. The pressure switch L, pertaining to the cylinder assembly 96a, corresponds in its function to the pressure switch M. The line 230 comprises a solenoid LS and is connected to the line MI. The line I91, connected to the mainsupply line 195, is adapted to be connected with the line 23l by closure of the switch D.

The switch C is shown in Figure 23, and is supported by the table I 0. The switch C is closed when the casing I31, hinged by means of the pivot 232 to 9. lug 233 on the table I 0, is moved from Figure 23 into Figure 24 position. To manually efiect this shifting movement, the casing I81 is provided with a handle 23 i. 3

The switch D is closed when the table ID has moved toward the left (Figure 2) to such an extent that the dog I83 engages the switch D. The line 23! comprises a solenoid DR and leads to a normally closed valve H which, when closed, connects the line 23! with the line 233, electrically connected to the main supply line 2 I 0. The valve H is adapted to be opened by a pin 235 connected with the rotating drum 32 when the pin 235, during its rotation, reaches a predetermined position. The pin 235, when rotating by degrees from the position shown in Figure 20, opens the normally closed valve I, thereby breaking electric connection between the line H2 and the line 236.

The line 236 comprises a solenoid ER and is adapted to be connected with a line 231. by closure of a switch E, which is normally open. The switch E is closed by the dog I83 when the table i 0, on its leftward movement with regard to Figure 2, has reached a predetermined position.

The line 221 is connected with the main supply line 105, and is also connected with a line 238, adapted to be connected with the line 239 by means of the relay blade ERzERs. Connected with the line 238 is a line 240 adapted to be connected with a line 221 by closure of the relay blade ERi. The blades ER1,ER2ER3 and ERA are controlled by the solenoid ER. Similarly, the blades DRl, DRzDR: and DR; are controlled by the solenoid DR. The line 2M is normally connected by the switch B with the line 2| l. The

line 230 is connected with one end of the solenoid Figure 21 shows the most essential elements of Figure 20 in simplified form in such a manner that the switches controlled by the various solenoids are arranged in a vertical row. For instance, from Figure 21 it will be visible that the switches DRA, DB1 and DRzDRa, arranged in a single vertical row, are controlled by the solenoid DR. Similarly, the solenoid ER controls the switches ERI, ERzER: and ER4.

Figure 22 indicates, for instance, that when the solenoid ES4DS4 is energized, the table moves either to the left or'to the right. Figure 22 also indicates that, during the first movement of the drum 32 by an angle of 180 degrees, the solenoids E81, E82 and ES: are energized, whereas, during the second movement of the drum 32 by 180 degrees, the solenoids DS1, D82 and D8: are energized.

It may now be assumed that the work piece II has been properly located on the table I0, and that the table-I is in its outermost right hand position. four-way valve I66- is open, since the solenoid ES4DS4 is energized. The energizing circuit for the solenoid ES4DS4 comprises main supply line 2I0, line 2I2. solenoid ES4DS4, switch M, line 2I3, relay blade ER4, line 2I5, relay blade DB4, lines 2I6 and 2I'I. and main supply line I95.

It may further be assumed that the casing I81 is in the position of Figure 24, at which the switch C is closed. It may also be assumed that the cross slides 26 and 26a are in their outermost position. at which the cams I88 and I89 close the normally open switches I92 and 206 respectively.

In order to move the table I0 into operative position, the operator presses the switch A so as to establish electric connection between the lines 201 and 209. Electric current will then flow .from the main supply line I95 through line I91,

switch C, which is now closed since the casing I81 is in Figure 24 position. line I96, now closed switch I92 line I94, switch 266, line 206, terminal 201 now engaged by the witch A, line 209, solenoid D81, and the main supply line 2I0. In this way, the solenoid DSi will be energized, thereby shifting the master valve I58 (Figure 19) into position for establishing fiuid connection between the conduit I52 and the conduit I61.

Since, as mentioned above, the valve I66 is open so as to establish fluid connection between the conduits I63 and I65 leading to the tank I3I, pressure fluid from the p I29 H flows through conduit I61 to the right hand end of the cylinder I68, thereby moving the plunger I69 and the table I0, connected thereto, toward the left, while the fluid expelled from the left hand end of the cylinder I68 passes through the conduit I66 and the master valve I58, the conduit I 59, retarding valve I60, conduit I6 I, retarding valv I62, conduit I63, valve I64 and conduit I65 tothetank I3I.

When the table I0 and, therefore, also the work piece II, supported thereby, approaches the predetermined position at 'which the machining operation is to be started, the operator gradually.

closes the choke 266 in the conduit I52 of the hydraulic system shown in Figure 19, thereby interrupting the supply of pressure fluid to the right hand end of the table cylinder I68 and bringing th table I0 to a stop. Immediately after the table started its movement from its outermost position to the last mentioned position, the operator may release the switch A so that it returns to its initial position. Although this will break the energizing circuit for the solenoid DSi, pertaining to the master valve I58, it 'will At this time, the electrically controlled not afiect the position of the master valve I58, which stays in the position into which it was last moved.

The operator now manually controls the fourway valves 245, 24511 (Figure 3) by actuating the levers 246, 286a so as to supply pressure fluid to the cylnders I28 and I28 a. As a result thereof, the piston rods I26 and I26a, pertaining to the pistons in the cylinders I28 and I28a, move the cross slides 26, 28a toward the work piece, thereby also moving the grinding wheels and 20a toward the work piece. When the pistons in the cylinders I28 and I28a have reached the end of their stroke, the cross slide 26, 26a, with the i5 grinding wheels 20, 20a, stop.

The operator then actuates'the hand wheels II1, Illa to bring the grinding wheels 20, 20a into proper engagement with the work piece, in the manner previously described under Op- 20 eration of the cross slides, The operator now actuates the hand wheels I04, I06a to establish the desired eccentricity between the axes of rotation of the rinding wheels 20, 20a and the axes of rotation of the respective drum. It may now be assumed that, after this adjustment, the grinding wheels are in the position shown in dot-dash lines in Figure 4.

It will be noted that, when the cross slides move from their outermost position toward the 30 work piece, they release the pins or contacts I90 and 205 so that the switches I92 and 286,0pen. This, however, has no effect on the energizing circuit for the solenoid DSi, which circuit as mentioned above, was already broken by the return of the switch A to its initial position. When the cross slides 26, 26a have been moved to their inward position, the cams I88 and I89 respectively engage the pins I9I, 202, thereby closing the switches F and G. This will establish an electric circuit comprising the main supply line I95, switch C, line I96, solenoid 2M, 'iine I99, switches F and G, line 200 and main supply line 2"].

Due to the energization of the solenoid 2I4, the switch N opens, thereby interrupting the energization of the solenoid ES4DS4 so that the valve I64 closes. No fluid from the table cylinder I68 can therefore escape to exhaust, so that, since fluid pressure prevails in the conduit I 61. the table is positively held stationary. All parts are now in position for starting the actual machining operation.

To initiate this operation, the operator shifts the casing I81 from Figure 24 into Figure 23 position, thereby opening the switch C so that the energizing circuit for the solenoid 2I4 is broken and the switch N again closes. This again establishes the energizing circuit for the solenoid ES4DS4 so that the valve I66 again opens. Now the operator opens the choke 266 to a desired extent, in accordance with the desired speed of the table I0. Since, as previously mentioned, the valve I64 is open, due to the en- 65 ergization of the solenoid ES4DS4, while the master valve I58 establishes fluid connection between the pressure line I52 and the conduit I 61, the table I0, and thereby also the work piece II, now moves toward the left with regard to Fig- 7 ures 4 and 19. In this way, the grinding wheels 20 and 20a will machine the straight surfaces I08, I080. (Figures 4 and 8).

Shortly before the grinding wheels, during this operation, reach the position indicated in dot-dash lines in Figure 5, the cam I82 actuates the lever arm I62, pertaining to the retarding valve I62, so as to throttle the flow of fluid through the valve I62. This causes a gradual reduction in the speed of the table so that the latter comes to a gradual stop at the end of its leftward movement, at which the grinding wheels substantially occupy the position shown in Figure 5.

When the grinding wheels are substantially in the position indicated in dot-dash lines in Figure 5, so that they are about to begin machining of the adjacent curved surfaces (only one surface 28 being shown), the dog I83 closes the switch E, thereby closing the energizing circuit for the solenoid ER. This circuit comprises main supply line I95, line 231, switch E, line 236, solenoid ER, the normally closed switch I, which is closed at this time, line 2| 2 and main supply line 2I0.

Energization of the solenoid ER causes closure of the relay blades ERzERs and ER1, while opening the relay blade ER4. The opening of the relay blade ER4 breaks the energization for the solenoid ES4DS4 so that the valve I64 closes. The table I is, therefore, positively stopped. Closure of the relay blade ERI establishes a'circuit, which circuit comprises main supply line I95, lines 231, 238 and 240, blade ERl, line 24I, switch B, line 2, solenoid E81 and main supply line 2I0. This causes energization of the solenoid E81, thereby reversing the position of the master valve I58 so as to establish fluid connection between the pressure line I52 and conduit I66, while connecting the line I61 with the line I59. However, since the valve I 64 controlling the exhaust through conduits I59, I6I and I63 is closed, no movement of the table I0 is possible at this time.

Closure of the relay blade ERzERh closes the energizing circuit for the solenoids E52 and ES3,

which circuit comprises the main supply line I 95,-

lines 231 and 238, relay blade ERzERa, line 239, solenoids E82 and ESz, line 242 and main supply line 2I0. Energization of the solenoids E82 and E83 controls the position of the four-way valves I38 and I so as to cause rotation of the seemental gears connected to the rotatable drums (only one gear 36 and one drum 32 being shown) from Figure 13 into Figure 16 position, in which latter position they are locked, in the manner previously described under Rotative movement of the drum."

While the gears and thereby the drums are moving from Figure 13 into Figure 16 position, the grinding wheels, due to their eccentricity with regard to the axes of rotation of the drums, perform such a movement that the periphery of the grinding wheels machines the adjacent curved surface, as indicated in Figure 6. When, during this movement, the piston 54 is on its way to the left side of the cylinder 55 and passes beyond the port 221, the pressure fluid acting on the piston 54 is conveyed through the conduit 226 to the pressure switch K so as to close the same. A similar operation in the cylinder 55a causes closure of the pressure switch J.

Closure of the switches J and K causes energizationof the solenoids JS and KS, pertaining,

to the valves I34 and I10 respectively. As a result thereof, the valves I34 and I10 are reversed. thereby bringing about movement of the rack 39 in the cylinder 45 from its extreme right hand position; with regard to Figure 14, into the position shown in Figure 16 through the position of Figure 15. A corresponding movement is effected with the rack in the cylinder 450. As will be obvioiis, during this movement, which occurs while the rotatable drums are being rotated by 180 v degrees, the pressure switches J and K again open, thereby breaking the energizing circuit for the solenoids JS and KS. This, howev er, does not change the position of the valves I34 and I10.

When the gears have reached Figure 16 position, the grinding wheels are in the position indicated in dot-dash lines indicated in Figure 1, in which they are about to begin machining of the straight surfaces 91, 91a. In this position the drums (only one drum 32 being shown) occupy such a position that the pin 236 has moved from Figure 20 position by l80degrees so as to open the switchI, thereby breaking the energizing circuit for the solenoid ER. As a result thereof, the relay blades ER1 and ER2ER3 return to their open positions, while relay blade EH4 returns to its closing position. The opening of the relay blade ERaER: causes deenergization of the solenoids E82, ES: without, however, efiecting a change in the position of the valves I38 and I15. Opening ofthe relay blade ERI breaks the energizing circuit for the solenoid ESi. This has no efiect on the position of the master valve I68.

Closure of the relay blade ER causes energization of the solenoid ES4DS4. The energizing circuit for the solenoid ES4DS4 comprises main supply line I95, lines 2" and 2I6, relay blade DB4, line 2I5, relay blade ER4, line 2I3, switch N, line 2 I 2, solenoid ES4DS4 and main supply line 2I0. Consequently, the valve I64 opens and, inasmuch as, due to the last effected shifting movement of the'valve I58 by solenoid ESi, pressure fluid from the pump I29 now flows through conduit I66 to the left hand end of the table cylinder I68, the table II), together with the work piece II supported thereby, begins its rightward movement. The grinding wheels 20, 20a therefore machine the straight surfaces 91, 91a, as indicated in Figure '1.

It is obvious that-as soon as the table I0 has moved by a predetermined distance toward the right, it releases the switch E so that the latter again opens. When the grinding wheels approach the left hand end of the straight surfaces 91, 91a, the cam I84 actuates the lever arm I60, pertaining to the retarding valve I60, was to throttle the flow' of fluid therethrough. This causes a gra'dual reduction in the speed of the table so that the latter comes to a gradual stop at the end of its rightward movement, at which the grinding wheels are just in position to engage the curved left hand surfaces of the work piece I I. In this position, the dog I85 closes the switch D, thereby closing the energizing circuit for the solenoid DR. This energizing circuit comprises main supply line I95, line I91, switch D, line 23I, solenoid DR, now closed switch H, line 233 and main supply line 2 I0. Energization of the solenoid DR. causes closure of the relay blades DB1 and DRzDRa, while causing the relay blade DB4 

